Renormalization of crossing probabilities in the planar random-cluster model
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Datum
2020Typ
- Journal Article
Abstract
The study of crossing probabilities (i.e., probabilities of ex-istence of paths crossing rectangles) has been at the heart of the theory of two-dimensional percolation since its beginning. They may be used to prove a number of results on the model, including speed of mixing, tails of decay of the connectivity probabilities, scaling relations, etc. In this article, we develop a renormalization scheme for crossing probabilities in the two-dimensional random-cluster model. The outcome of the process is a precise description of an alternative between four behaviors: • Subcritical: Crossing probabilities, even with favorable boundary conditions, converge exponentially fast to 0. • Supercritical: Crossing probabilities, even with unfavorable boundary conditions, converge exponentially fast to 1. • Critical discontinuous: Crossing probabilities converge to 0 exponentially fast with unfavorable boundary conditions and to 1 with favorable boundary conditions. • Critical continuous: Crossing probabilities remain bounded away from 0 and 1 uniformly in the boundary conditions. The approach does not rely on self-duality, enabling it to apply in a much larger generality, including the random-cluster model on arbitrary graphs with sufficient symmetry, but also other models like certain random height models. © 2020 Independent University of Moscow Mehr anzeigen
Publikationsstatus
publishedExterne Links
Zeitschrift / Serie
Moscow Mathematical JournalBand
Seiten / Artikelnummer
Verlag
Independent University of MoscowOrganisationseinheit
09584 - Tassion, Vincent / Tassion, Vincent